added resistance gradient

简明释义

附加阻力梯度

英英释义

例句

1.The new design of the pipeline incorporates an added resistance gradient 附加阻力梯度 to minimize fluid turbulence.

新设计的管道结合了<添加阻力梯度>以最小化流体湍流。

2.In the context of sports science, understanding the added resistance gradient 附加阻力梯度 can help improve athletes' performance.

在体育科学的背景下，理解<添加阻力梯度>可以帮助提高运动员的表现。

3.The study revealed that the added resistance gradient 附加阻力梯度 significantly influences the energy efficiency of the system.

研究显示，<添加阻力梯度>显著影响系统的能效。

4.The added resistance gradient 附加阻力梯度 in this material can affect its thermal conductivity.

这种材料中的<添加阻力梯度>会影响其热导率。

5.Engineers need to calculate the added resistance gradient 附加阻力梯度 when assessing the performance of the new vehicle model.

工程师在评估新车型的性能时需要计算<添加阻力梯度>。

作文

In the world of physics and engineering, understanding various forces and their interactions is crucial. One concept that often arises in discussions about fluid dynamics, structural engineering, and even biomechanics is the term added resistance gradient. This phrase refers to the additional resistance that an object encounters when moving through a fluid or when subjected to external forces. The added resistance gradient can significantly impact the performance and efficiency of systems ranging from ships navigating through water to athletes swimming in a pool.To illustrate the importance of the added resistance gradient, consider the case of a ship sailing through the ocean. As the vessel moves forward, it displaces water, creating waves and turbulence. This displacement generates a certain amount of resistance that the ship must overcome to maintain its speed. However, as the ship accelerates, the increase in speed leads to a change in the flow of water around the hull, resulting in an increase in the added resistance gradient. This means that not only does the ship have to contend with the initial resistance, but it also faces additional challenges due to the changing dynamics of the water around it.Similarly, in the realm of sports, swimmers must be acutely aware of the added resistance gradient they encounter in the water. When a swimmer dives into a pool, they create a disturbance in the water, which can lead to increased drag. As they swim faster, the shape of their body and the angle at which they enter the water can alter the added resistance gradient, affecting their overall speed and efficiency. Swimmers often train to minimize this resistance by perfecting their techniques and streamlining their movements, demonstrating how critical an understanding of this concept can be for athletic performance.Moreover, in structural engineering, the added resistance gradient plays a vital role in designing buildings and bridges. Engineers must account for the forces acting on structures, including wind resistance and the weight of materials. As a structure experiences various loads, the added resistance gradient can change, influencing the stability and safety of the design. By analyzing these gradients, engineers can ensure that their structures can withstand the forces they will encounter over time.In conclusion, the concept of added resistance gradient is fundamental across multiple disciplines. Whether it is in maritime navigation, competitive swimming, or structural engineering, recognizing and understanding this phenomenon allows professionals to optimize performance and enhance safety. By studying the added resistance gradient, we gain insights into how objects interact with their environments and how we can improve our designs and techniques for better outcomes. As we continue to explore the intricacies of physics and engineering, the added resistance gradient will undoubtedly remain a key area of focus, providing valuable lessons and applications in our ever-evolving world.

在物理和工程的世界中，理解各种力量及其相互作用至关重要。一个在流体动力学、结构工程甚至生物力学的讨论中经常出现的概念是“附加阻力梯度”这个术语。它指的是当物体在流体中移动或受到外部力量作用时，物体遇到的额外阻力。“附加阻力梯度”可以显著影响从船只在水中航行到运动员在游泳池中游泳等系统的性能和效率。为了说明“附加阻力梯度”的重要性，可以考虑一艘船在海洋中航行的案例。当船只向前移动时，它会排开水，产生波浪和湍流。这种排开会产生一定量的阻力，船只必须克服这些阻力以保持速度。然而，随着船只加速，速度的增加会导致水流绕过船体的方式发生变化，从而导致“附加阻力梯度”的增加。这意味着船只不仅要应对初始阻力，还面临着由于周围水域动态变化而带来的额外挑战。同样，在体育领域，游泳运动员必须清楚他们在水中遇到的“附加阻力梯度”。当游泳者跳入游泳池时，他们在水中造成扰动，这可能导致阻力增加。当他们游得更快时，身体的形状和进入水中的角度会改变“附加阻力梯度”，影响他们的整体速度和效率。游泳者通常通过完善技术和流线型动作来减少这种阻力，展示了理解这一概念对运动表现的重要性。此外，在结构工程中，“附加阻力梯度”在建筑和桥梁设计中发挥着至关重要的作用。工程师必须考虑作用于结构的力量，包括风阻和材料的重量。当结构经历各种载荷时，“附加阻力梯度”可能会发生变化，影响设计的稳定性和安全性。通过分析这些梯度，工程师可以确保他们的结构能够承受随时间变化的力量。总之，“附加阻力梯度”的概念在多个学科中都是基础。无论是在海事导航、竞技游泳还是结构工程中，认识和理解这一现象使专业人士能够优化性能并增强安全性。通过研究“附加阻力梯度”，我们获得了关于物体如何与其环境相互作用以及如何改善我们的设计和技术以获得更好结果的见解。随着我们继续探索物理和工程的复杂性，“附加阻力梯度”无疑将继续成为一个关键关注领域，为我们不断发展的世界提供宝贵的经验教训和应用。